材料科学
再生(生物学)
自愈水凝胶
导电体
生物材料
压电
生物医学工程
组织工程
间充质干细胞
纳米技术
伤口愈合
生物相容性材料
干细胞
骨愈合
骨髓
细胞
生物相容性
作者
Guanbo Min,Peng Yue,Wenjun Wang,Wenjun Wang,Tingyu Wang,Yaqi Zhang,Zetao Yin,F. Lv,Xuanli Dong,Shuxing Xu,Kun Xu,En Zhao,Cheng‐Yu Li,Ke Wang,Xin Zhao,Jessica M. Rosenholm,Weiguo Wang,Weiguo Wang,Cheng Huang,Wei Tang
标识
DOI:10.1002/adfm.202515477
摘要
Abstract Critical bone defects require interventional treatment as they exceed the body's natural repair capacity. The emerging approaches involve implantable biomaterial or devices, but persist challenges in biodegradability, low cell migration, and differentiation efficiency, complex surgery procedures. This study presents a biodegradable piezoionic hydrogels assembly scaffoldoid composed of piezoelectric glycine‐based hydrogel and Li + ‐contained injectable conductive hydrogel. Upon ultrasound stimulation, the piezoelectric hydrogel generates an electric field that propagates through the conductive hydrogel. The regulation of Li + concentration to enhance the electrical conductivity of conductive hydrogels facilitates the recruitment of bone marrow mesenchymal stem cells (BMSCs) by the assembly. Under the synergistic stimulation of electrical signals and Li + , namely, dual‐stimuli, the recruited BMSCs activated their PI3K/AKT and β‐catenin/TCF7/CCN4 signaling pathways, thereby promoting the high expression of osteogenic genes such as RUNX2. Moreover, the conductive hydrogel is injectable, serving as a conformal scaffoldoid for full wound coverage, and the piezoelectric hydrogel can be seamlessly attached upon with the conductive hydrogel at the wound site, thereby simplifying the interventional repair procedures.
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